Frequently asked questions and answers about Ring Pumps

What is the difference between a conventional peristaltic pump and the Ring Pumps?

Our Ring Pump was developed to extend the tube life of conventional tube pumps (roller pumps). For more information, please see the link below.

Comparison with conventional tube pump (roller pump).

Various tubing of the Ring Pumps

An important part of the Ring Pump is the tube through which the liquid passes. You need to choose the right tube for the liquid you are using. Improper use of the tube can cause problems by causing the liquid to damage the tube and affect the life of the tube, or to elute the components of the tube into the liquid and change the components of the liquid.
If you provide the liquid to be used, we can conduct a liquid contact test using various tubes and select the tube based on the result. Please let us know.

The main tubes used in our Ring Pumps are as follows.

* PharMed, Versilon and Tygon are registered trademarks of Saint-Gobain, France.
* Transmaster is a registered trademark of Mitsuboshi Co., Ltd.

Please tell me about the pulsation of the Ring Pump

When the flow rate (flow speed) of the discharged flow is not constant and increases or decreases periodically, it is called "flow is pulsating" or "pulsating flow". The discharge flow of the Ring Pump has pulsation.

In this way, a general Ring Pump has a pulsation in which the discharge amount becomes negative (backflow) in one cycle for each rotation of the eccentric rotor.

By using the two connected pump with press points shifted by 180 degrees, such as the RP-2S, RP-2GII and RP-WII series, the range of pulsation change can be reduced.

The table below shows a typical example of the relation between the time and the discharge rate of the RP-S series (single channel Ring Pump) and RP-2S series (double channel Ring Pump). In the normal pump, the discharge amount has changed to the minus range. This part means that there is a backflow.

* The discharge rate in the catalog and website is the average discharge rate in the figure.

Please tell me about the discharge/suction performance

Below we provide information on the suction performance and discharge performance of the pump using the PQ curve that shows the relation between the suction/discharge height and the discharge rate.

The figure below shows an example of the RP-KII series P-Q curve and an explanation of the suction/discharge heights.

The suction height is the height from the surface of the water to be sucked to the pump.
The discharge height is the height from the pump to the discharge port when discharging into the air, and the height to the water surface when discharging into the water in the container.

In the P-Q curve the discharge amount is set to 100% when the suction height and the discharge height are 0 m, that is, the suction water surface, the discharge port, and the pump are set to the same height.

Measure the rate of change in the discharge rate when the suction height is increased while the discharge height remains 0 m, and the rate of change in the discharge rate when the suction height is increased while the suction height remains 0 m. The P-Q curve combines those measurements in a single graph.

In the P-Q curve, the discharge amount decreases as the suction height increases, but the effect on the discharge amount is small even if the discharge height increases. The suction force depends on the elastic restoring force of the tube. As the suction height increases, the force required to suck the water increases, so the amount of water sucked decreases. As a result, the discharge rate is also reduced.

Discharging is performed by sequentially squeezing the tubes with the power of a motor. Since there is a margin in the motor power, the discharge rate hardly changes at a height of about 5 m.
The curve changes depending on the model of the Ring Pump, but the Ring Pump has this tendency.

* The discharge rate of catalogs and websites is the discharge rate of water when the suction height is 0 m and the discharge height is 0 m.